Apparatus for releasably holding tool

ABSTRACT

A tool holder comprising: a boss configured to accept the tool and having a can  4  which may be inserted into a recess on a carrier; a movable carrier in communication with a securing pin providing for the releasable engagement of the tool when the tool is placed on the boss and the tool is rotated when engaged; and, a carrier positioner in simultaneous communication with a carrier containment device and one or more movable carriers.

CROSS REFERENCE

This application is a Continuation-in-Part Application of U.S. patent application Ser. No. 10/422,481, filed on Apr. 24, 2003, entitled APPARATUS FOR RELEASABLY HOLDING TOOL by inventor Stanley d. Winnard (Attorney Docket No. 41757-P008US).

This application is related to U.S. patent application entitled APPARATUS FOR RELEASABLY HOLDING TOOL by inventor Stanley D. Winnard (Attorney Docket No. 41757-P008P2) filed concurrently herewith.

STATEMENT OF FEDERALLY SPONSORED RESEARCH/DEVELOPMENT

This application is not federally sponsored research/development.

REFERENCES TO SEQUENCE LISTING

This application is not referenced to any microfiche appendix.

BACKGROUND OF THE INVENTION

The present invention relates to tool holders and more particularly to an apparatus for securely holding a socket tool that may be easily released by a user.

Almost every mechanic, maintenance technician and do ityourselfer around the world has at least one set of sockets. A socket set is practically indispensable for anyone who needs to tighten or loosen bolts and nuts. Many people, in fact, have multiple sets of sockets. Metric, standard, deep, 6 point, 12 point, ¼″ drive, ⅜″ drive, ½″ drive and impact are just a few of the different types of sockets. Some industries such as the aircraft heavy industrial machinery industries use ¾″ drive or even 1″ drive sockets. These types of sockets are found in a number of combinations; for example, a person may have an entire set of metric size, 6 point, ⅜″ drive, deep sockets in addition to other more common combinations.

BRIEF SUMMARY OF THE INVENTION

While the making and using of various embodiments of the present invention are discussed in detail below, it should be appreciated that the present invention provides for inventive concepts capable of being embodied in a variety of specific contexts. The specific embodiments discussed herein are merely illustrative of specific manners in which to make and use the invention and are not to be interpreted as limiting the scope of the instant invention.

Although having many types of sockets is beneficial to have the correct tool for any job, storing and organizing each socket can be a daunting task. Many sockets tend to be small, and are thus easily misplaced around a home or shop. Additionally, sockets are usually cylindrical and therefore can easily roll great distances if dropped on a smooth garage floor. This problem is exasperated given the inadequate storage devices that are supplied with many socket sets.

For example, many sockets are supplied in a molded plastic case that may have wells to cradle each socket. Although easy for a user to locate and remove, this type of storage device has often become a nightmare for many socket owners. The cases are designed to “sandwich” the sockets when closed to prevent socket movement when the case is transported. The supplied cases, however, tend to wear and allow sockets to freely mix within the case. A user must spend valuable time re sorting the sockets so that a proper socket may be easily located for a particular job. On a more catastrophic level, many users have lifted their molded plastic socket case only to find that the clasps on the case had opened or broken. The result is a disheartening crash of tools that typically scatters every socket into the furthest reaches of the garage or work area. Many sockets have been permanently lost in such an event.

An alternative to holding and organizing sockets in cases is by using a socket holding strip. These strips usually have multiple bent spring steel clips that are captured by a thin steel rail. The sockets are retained on the spring steel clips, which may slide along the rail. These strips tend to hold sockets very well when new. Great holding power, however, is not beneficial when a user attempts to remove a socket with oily or greasy hands. Additionally, the clips tend to lose their holding force after moderate use, which may result in sockets being inadvertently detached from the strip and lost.

Another example of contemporary art socket holders is disclosed in U.S. Pat. No. 5,467,870 (hereafter, “Whitaker.”) Unlike Whitaker, the instant invention teaches a socket holder having a carrier and a boss that are movable within a containment device. The socket holder of Whitaker teaches a plurality of attachment mechanisms which are longitudinally displaced in a fixed position apart from one another through the length of the rack. A suitable device serves to affix the bottom of each attachment mechanism to the upper surface of the rack such as an illustrated fastener 28; reference Whitaker column 3, lines 65-67, column 4, lines 1 and 2. Succinctly stated the socket holders of Whitaker are fixed position socket holders and are not moveable on individually positionable as are the instant invention's.

Whitaker further relies upon an axially displaced spring urged attachment member to provide a positive securing of the attachment member in both locked and unlocked positions. A compression ring that seems to be disposed intermediate the top surface of the attachment mechanism cam element and the top wall of the mounting member. Reference column 2, lines 60-64. Whitaker discloses in this matter a constant upward force required to be applied to the mounting member and its integral radial tab, with the result that whenever one of the mounting members is rotated or arcuately displaced to either limit of its movement, the tab will be forced upwardly into one of the recesses and thus effectively secure the arcuate disposition of the mounting member relative to the associated attachment mechanism.

The instant invention in its simplicity and uncomplicated manner neither discloses, teaches nor claims any of the convoluted spring biased forces to effectuate its purpose of securing a socket/tool reference further Whitaker column 5, line 5-37.

In stark contrast to the teachings of Whitaker, the instant invention provides the means by which a boss may also have a locking tab that may be molded into the boss. The locking tab may snap into a recess on the carrier or the locking pin when the socket holder has secured a socket. The action of turning the socket, locks and unlocks the locking tab from the recess and serves to give the user tactile feedback to indicate the socket is secured or released from the socket holder.

Considering the inadequacies of available socket holding devices, a socket holder that does not allow sockets to become disorganized or lost during transport is needed. Additionally, there is a need for a socket holder that does not hinder a user from removing a desired socket.

In accordance with one embodiment of the present invention, a socket holder has a carrier and a boss movable within the carrier. The boss is configured to accept the drive end of the socket. A locking pin within the boss releasably engages the boss to the socket when the boss is turned.

In another embodiment of the present invention a twist lock socket holder has a carrier that has a cam surface and a boss housed generally within the carrier. The boss is generally rotatable within a bearing surface of the carrier. The boss also has one or more cam followers. The cam followers generally engage the cam surface to urge the boss generally along an axis tangential to a horizontal plane of the carrier. A locking pin is housed generally within the boss, the locking pin is generally tangential to the horizontal plane of the carrier. A detent ball is housed within a detent in the boss. The detent ball is generally retained by a retaining surface on the locking pin and urged into a socket detent by a locking surface of the locking pin when the socket is placed on the boss and rotated.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the present invention, and the advantages thereof, reference is now made to the following description which is to be taken in conjunction with the accompanying drawings in which like reference numerals indicate like parts and wherein:

FIG. 1A depicts a sectional view of a socket holder according to one embodiment of the present invention;

FIG. 1B depicts a view of the lower end of a socket holder incorporating a locking mechanism according to one embodiment of the present invention;

FIGS. 2A-2E depict a socket holder carrier according to one embodiment of the present invention;

FIGS. 3A-3E depict a socket holder boss according to one embodiment of the present invention;

FIGS. 4A-4C depict a socket holder locking pin according to one embodiment of the present invention;

FIGS. 5A-5E depict a socket holder according to one embodiment of the present invention; and

FIG. 6 depicts a socket holder in a storage rail according to one embodiment of the present invention.

FIGS. 7-12 depict another embodiment of the instant invention wherein a improved guide channel and positioner enhance the independent and variable positioning of a socket holder within the holder's containment device.

DETAILED DESCRIPTION OF THE INVENTION

While the making and using of various embodiments of the present invention are discussed in detail below, it should be appreciated that the present invention provides many applicable inventive concepts that may be embodied in a wide variety of specific contexts. The specific embodiments discussed herein are merely illustrative of specific ways to make and use the invention and do not delimit the scope of the invention.

Referring now to FIGS. 1A and 1B, a socket holder 10 according to the present invention is depicted. The socket holder 10 has a carrier 12 that houses a boss 14. The boss 14 has a drive end 16 that fits within a drive of a socket 50. The drive end 16 may be sized to accept a wide range of sockets sizes from ¼″ drive to 1″ drive, for example. The drive end 16 may also be configured to accept a 6 point box end wrench, for example. Other configurations of the drive end 16 to hold other tools will be apparent to those of ordinary skill in tool design. The drive end 16 has a detent 18 that houses a detent ball 20. The detent ball 20 may move freely within the detent but may be captured and locked into place by a locking pin 22 that is housed within a central portion of the boss 14 and drive end 16. The locking pin 22, which will be described in greater detail below, serves to urge the detent ball 20 into a socket detent 24. As a user turns the socket 50 clockwise, for example, the boss 14 moves down along the axis of the locking pin 22. Because the end of the locking pin 22 has a contoured profile, the wider profile of the locking pin 22 moves the detent ball 20 into place.

When the detent ball 20 is in the socket detent 24, the socket 50 is securely attached to the socket holder 10. The detent ball 20 may be magnetized to help urge the detent ball 20 into the socket detent 24 when a ferrous socket 50 is placed on the drive end 16. The locking pin 22 may also have a locking detent (not shown) that releasably secures the detent ball 20 when the socket 50 is secured by the socket holder 10. The locking detent provides an extra measure of security that prevents the socket 50 from being inadvertently detached from the socket holder 10.

The boss 14 may also have a locking tab 13 that may be molded into the boss 14. The locking tab may snap into a recess 15 on the carrier 12 or the locking pin 22 when the socket holder 10 has secured the socket 50. The action of turning the socket 50 locks and unlocks the locking tab 13 from the recess 15 and serves to give the user tactile feedback that indicates that the socket 50 is secured or released from the socket holder 10. The locking tab 13 also prevents the socket 50 from being inadvertently detached from the socket holder 10. Other mechanisms for preventing the socket holder 10 from inadvertently releasing the socket 50 will be apparent to those having ordinary skill in the art of mechanics.

Turning now to FIGS. 2 and 3, one embodiment of the carrier 12 of the socket holder 10 is depicted in greater detail. The carrier 12 has a generally cylindrical boss opening 26 that accepts the boss 14. A bearing surface 28 engages the outer surface of the boss 14 to allow rotation and axial movement of the boss 14 within the carrier 12. Depending on the application, the clearance between the boss 14 and the bearing surface 28 may be varied. For example, a loose fit clearance is generally preferred for ease of operation of the socket holder 10 and manufacturing cost savings but a close fit clearance may be used to enhance the perception of quality or to prevent debris from collecting between the boss 14 and the carrier 12.

The carrier 12 may be, for example, injection molded plastic; machined, stamped or cast metal or alloys; carbon fiber; and the like. The carrier 12 may have a non transferable magnet or magnetic material attached to a portion of the carrier 12 so the socket holder 10 may be easily and conveniently attached to a surface such as a tool box or other surface of a work piece such as a car body or an airplane wing. Alternatively, double sided adhesive tape may be attached to a surface of the carrier 12 to facilitate more permanent mounting to workshop surfaces, tool boxes and the like. Several socket holders 10 may also be attached to a single rail or within a strip of channel section. Attaching multiple socket holders 10 allows the user to organize an entire set of sockets in a single location.

Additionally, a hanging tab 29 may be incorporated into the carrier 12. The hanging tab 29 may be designed to hang the socket holder 10 directly to a hook or rod in a store display. As a result, the socket holder 10 may be marketed holding a socket 50 and may be immediately displayed in a store after it arrives from a distributor without any additional packaging. After a user purchases the socket holder 10, the hanging tab 29 may be snapped, broken or removed from the carrier 12 and the socket holder 10 can be placed on a rail or strip of channel section for storage.

The carrier 12 may also be manufactured to aid the user in identifying a particular socket 50. The carrier 12 may also be colorcoded to differentiate between standard and metric sizes or drive end sizes, for example. Additionally, the carrier may be marked to indicate the particular size of the socket 50, such as 9/16″ or 10 mm, for example. Other forms of socket identification may be incorporated into the boss 14. For example, a post (not illustrated) may be molded or otherwise attached to the top surface of the drive end 16. This post may extend through the socket 50 and be visible above the socket 50 when the socket 50 is releasably attached to the socket holder 10. The post may be color coded or it may be marked according to the size or configuration of the socket 50. The post may also have an indicator that shows the user whether the socket 50 is locked into place or which direction to turn the socket 50 to the locked or unlocked positions.

The carrier 12 has a cam surface 30 that serves to move the boss 14 along the axis of the locking pin 22 when the user rotates the boss 14 by twisting the socket 50. As depicted in FIG. 3, one or more cam followers 32 on the boss 14 follow the contours of the cam surface 30 when the boss 14 is rotated. In one embodiment, for example, the cam surface 30 and the cam follower 32 may be one or more screw threads having a large pitch. Other configurations for effecting axial movement of the boss 14 with respect to the locking pin 22 will be apparent to those having ordinary skill in the art of mechanics.

Referring now to FIG. 4, the locking pin 22 according to one embodiment of the present invention is depicted. The locking pin 22 has a base 34. In this particular embodiment, the locking pin 22 is a separate component of the socket holder 10. In other embodiments, however, the locking pin 22 and base 34 may be incorporated into the carrier 12 as a single piece. This single piece, for example, may be molded plastic, machined metal or the like to reduce required pieces to assemble the socket holder 10 and thereby increase manufacturing efficiency.

In this embodiment, the locking pin 22 has a retaining surface 36 and a locking surface 38. The retaining surface 36 serves to hold the detent ball 20 (not shown) within the detent 18 (not shown) when the boss 14 (not shown) is extended along the axis of the locking pin 22. When the boss 14 (not shown) is rotated and retracted along the axis of the locking pin 22, the boss 14 (not shown) moves down onto the locking pin 22. The locking surface 38 consequently urges the detent ball 20 (not shown) further into the detent 18 (not shown) and a portion of the detent ball 20 (not shown) extends into the socket detent 24 (not shown). The socket 50 (not shown), therefore, is securely held by the socket holder 10 (not shown).

The locking surface 38 may have a locking detent (not illustrated) that securely captures the detent ball 20 (not shown) when the boss 14 (not shown) is in the locked position. The locking detent serves as an additional measure of security to prevent the socket holder 10 (not shown) from inadvertently releasing the socket 50 (not shown). To secure and release the socket 50 (not shown) from the socket holder 10 (not shown), the user must overcome slightly more resistance to move the detent ball 20 (not shown) from the locking detent. Other mechanisms for preventing the socket 50 (not shown) from inadvertently releasing from the drive end 16 (not shown) will be apparent to those having ordinary skill in the art of mechanics.

Turning now to FIG. 5, an assembled socket holder 10 according to one embodiment of the present invention is depicted. As described above, the locking pin 22 fits generally within the carrier 12 and the boss 14. A shoulder 40 may be incorporated into an assembly that includes the carrier 12 and the locking pin 22. The shoulder may include a snap ring (not illustrated) that engages a mating surface within the boss 14. The shoulder 40 may also include the cam surface 30 (not shown) that engages the corresponding cam follower 32 (not shown) within the boss 14. The cam surface 30 (not shown) and the cam follower 32 (not shown) may be embodied as threads that have a large pitch.

Using the snap ring on the shoulder 40 simplifies the manufacturing process of assembling the socket holder 10. Manufacturers can easily assemble the socket holder 10 by inserting and locating the detent ball 20 within the detent 18 and snapping the boss 14 into place on the carrier 12. The detent ball 20 may be located in the detent 18 using a magnet, for example. Other methods of assembling the socket holder 10 will be apparent to those having ordinary skill in the art of manufacturing.

A rail 44 for holding one or more socket holders 10 is depicted in FIG. 6. In this particular embodiment, the rail 44 has one or more channels 46 that are configured to accept one or more tabs 42 on the carrier 12 of the socket holder 10. Multiple socket holders 10 may be added to the rail 44 by removing an end cap 48 and sliding the socket holders 10 into the channel 46. The channel 46 may be configured to overlap a top surface of the boss 14 to redundantly secure the boss 14 within the carrier 12. This redundant measure of security is important to industries concerned with management and prevention of foreign objects and debris (FOD).

The rail 44 may be supplied in various lengths to accept large or small socket sets. The rail 44 may also be color coded according to socket type or have labels to identify the location of different sockets within the rail 44. The rail 44 may be manufactured from plastic, metal, carbon fiber and the like. The rail 44 may also have a nontransferable magnet or double sided tape to attach the rail 44 to a work surface or tool box. The user may consequently assemble a set of sockets 50 that are customized for a particular job on the rail 44 and secure the rail 44 to the particular work piece.

Referring now to FIGS. 7-12 wherein another alternative embodiment of the present invention is depicted. In FIGS. 7-12 it is shown where the instant invention is disclosed as a tool holder comprising a boss 103 configured to accept a tool (not shown) and having a carrier 107 which may be inserted into a recess 105 within a carrier 117.

The carriers 107 as identified in FIGS. 7-12 are in communication with a securing pin 110 which provides for the releasable engagement of a tool when the tool is placed upon and secured by boss 103 and the tool is rotated. A carrier positioner 115 is in simultaneous communication with a carrier containment device 120 and one or more movable carriers 107. The boss 103 has one or more cams 104 which engage a cam recess 105 on the carrier 107, with the cam 104 following the recess 105 to cause and allow the boss 103 to move axially with respect to a central access of the boss 103 when rotated upon the carrier 107. The cam recess 105 as depicted in the illustrations may further comprise recess lobes 130 to accommodate the cam 104 configuration and provide for tactile sensation whenever a receivingly dimensioned cam 104 is positioned or secured within a recessed lobe portion 112 of the recess 105.

With reference to the securing pin 110 of the invention embodiment illustrated in FIGS. 7-12, it may be observed where a securing surface 125 on the pin 110 urges a detent ball 116 into engagement with a recess on a tool (not shown) when the boss is rotated upon the securing pin 110 attached to, or in communication with the carrier 107. The securing pin 110 further illustrates a retaining surface 121 referenced most particularly in illustrations 9-10B where the retaining surface 121 retains the detent ball 116 within the detent when the detent ball is disengaged from the tool.

As most readily observed in FIG. 12 a carrier positioner 115 is in simultaneous communication with a carrier containment device 120 and one or more carriers 107. The carrier positioner is comprised of a resiliently compressible compound such as but not limited to latex based compounds and is insertably positioned within the carrier containment device, reference detail view FIG. 12. One or more compressible lobes 130 comprised of a resiliently compressible compound material such as latex base compounds may be attached to or otherwise made to communicate with a boss positioning surface 108 in a manner providing for the compressible positioning of said lobes 130 within a carriage storage channel 146. The combination of the lobes 130 and carrier positioner 115 allows for the variable and independed positioning of one or more carriers 107 within the channel areas 146 of the containment device.

Although the invention has been described in detail herein with reference to the illustrative embodiments, it is to be understood that this description is by way of example only and is not to be construed in a limiting sense. It is to be further understood that numerous changes in the details of the embodiments of the invention and additional embodiments of the invention will be apparent to and may be made by persons of ordinary skill in the art with reference to this description. It is contemplated that all such changes and additional embodiments are within the spirit and scope of the invention as claimed below. 

1. A tool holder comprising: a boss configured to accept the tool and having a cam which may be inserted into a recess on a carrier; a movable carrier in communication with a securing pin providing for the releasable engagement of the tool when the tool is placed on the boss and the tool is rotated when engaged; and, a carrier positioner in simultaneous communication with a carrier containment device and one or more movable carriers.
 2. The tool holder of claim 1, wherein the boss releasably engages the tool when the tool is rotated between about 10 degrees and about 90 degrees.
 3. The tool holder of claim 1, wherein the boss has one or more cams that engage a cam recess on the carrier, the cam following the cam recess and causing the boss to move axially with respect to a central axis of the boss when the boss is rotated upon the carrier.
 4. The tool holder of claim 1 wherein the cam recess has at least one recess lobe to accommodate the cam follower and provide for tactile sensation whenever the cam follower is positioned or secured therein.
 5. The tool holder of claim 1, wherein the boss has a detent ball within a detent to releasably engage the tool.
 6. The tool holder of claim 5, wherein a securing surface on the securing pin urges the detent ball into engagement with a recess on the tool when the boss is rotated upon the carrier.
 7. The tool holder of claim 5, wherein a retaining surface on the securing pin retains the detent ball generally within the detent when the detent ball is disengaged from the tool.
 8. The tool holder of claim 1, wherein the boss is configured to accept a ⅜″ drive socket.
 9. The tool holder of claim 1, wherein the boss is configured to accept a 1″ drive socket.
 10. The tool holder of claim 1, wherein the boss is configured to accept a ½″ drive socket.
 11. The tool holder of claim 1, wherein the boss is configured to accept a ¼″ drive socket.
 12. The tool holder of claim 1, wherein the securing pin is integral with the carrier.
 13. The socket holder of claim 14 wherein the carrier containment device further comprises a transferable magnet or magnetic material attached thereto.
 14. A twist lock socket holder comprising: a carrier having a cam recess and a securing pin, the securing pin having a retaining surface and a securing surface; a boss attachable to the carrier, the boss having one or more cam followers, the cam followers generally engaging the cam surface to urge the boss generally along a central axis of the securing pin when the boss is rotated; and a detent ball housed within a detent in the boss, the detent ball generally retained within the detent by a retaining surface on the securing pin and movable into a socket detent by a securing surface of the securing pin; and, a carrier positioner in simultaneous communication with a carrier containment device and one or more carriers.
 15. The twist lock socket holder of claim 14 wherein the carrier positioner is comprised of a resiliently compressible compound and is insertably positioned within a carrier containment device.
 16. The twist lock socket holder of claim 15 wherein the resiliently compressible compound is a latex based compound.
 17. The twist lock socket holder of claim 14 further comprising one or more compressible lobes positioned upon a boss positioning surface of the boss in a manner providing for the compressible positioning of said lobes within a carrier storage channel when the boss is rotated.
 18. The twist lock socket holder of claim 17 wherein the compressible lobes are comprised of a latex based compound.
 19. The twist lock socket holder of claim 14 further comprising a magnetic material or transferable magnet attached to the carrier containment device. 